...1. Functions of digestive system include: Convert food to energy Absorb digested nutrients Eliminate waste 2. Digestion process includes: Physical breakdown of food Chemical conversion and absorption Storage and eliminationNot assimilation – incorporation of nutrients into protoplasm 3. Lining of the abdominal cavity is Peritoneal membrane 4. The gastrointestinal (GI) tract is also called alimentary canal. 5. Buccal or oral cavity contains:TeethTongueSalivary glands 6. The salivary glands that get inflamed during mumps attack are parotid glands. 7. The saliva contains enzymes that convert starch into sugars. 8. Categories of teeth include:Incisors CaninesMolars 9. The organ that connects the buccal cavity (mouth) with the stomach is esophagus: 10. Common passage for food and air is pharynx. 11. The part of stomach that connects to small intestine is Pyloris. 12. The functions of stomach include:Storage of food Churning of food Chemical conversion of food 13. When the stomach is empty, its internal lining is thrown in folds called Rugae: 14. The part of small intestine joining the stomach is Duodenum 15. Pancreas and liver pour their juices in Duodenum. 16. The main function of small intestine is absorption of digested food. 17. Finger like projections in the small intestine that increase surface area and are richly supplied with blood capillaries to absorb the digested food are villi. 18. The part of large intestine joining the small intestine is...
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...butyl acetate). Acetic acid is a multimillion ton market with strong growth potential driven by downstream industry developments in vinyl acetate, polyesters, solvents, and specialties. Acetic acid provides a chemical platform serving several value chains focused on adhesives and coatings, apparel, engineering polymers, generic pharmaceuticals, oilfield chemicals and foodstuffs. Today, acetic acid is made in large scale mainly by methanol carbonylation, exploiting competitive sources of synthesis gas derived from natural gas and coal, with the latter focused mainly on China. Technology for downstream acetyls production is generally closely held by a few companies, in effect restricting market access, with some exceptions, as for applications like vinyl acetate and pure terephthalic acid, which are more accessible. Acetic acid can be derived from biomass for the food industry, but this is generally restricted to low scale operations. Hence, the concept behind this study is an analysis of the conversion of biomass into acetyls exploiting combinations of commercial processes at capacities commensurate with commercial scales of biomass processing. Nexant has examined acetyls production based on both fermentation ethanol and gasification platforms. As a platform chemical, ethanol can support ethylene production via dehydration. Combinations of ethylene and ethanol processing technologies can lead to cost effective acetyls and derivatives production, reflecting some actual commercial...
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...PACKAGING MATERIALS SAFETY EHA Consulting Group, Inc. Baltimore, MD 21208 www.ehagroup.com Overview A broad range of substrates comprise the list of approved food contact (direct and indirect) packaging materials FDA considers, controls and regulates direct contact packaging materials in the same manner as food ingredients Assumptions are that packaging substrates and all contacting substances can and may be consumed along with the food Manufacturers of packaging raw materials and finished, converted packages alike are expected to understand, apply and validate their processes for consistency, quality, safety and adherence to required methods and protocols Contact Material Regulations Direct and indirect contact packaging materials, substances, processing aids, coatings, adhesives and adjunct substances controlled and conditionally approved for use are described and referenced in 21CFR sections 173-182. Additional information, directives, procedures and controls may be found in sections of 21CFR dedicated to the specific food type (i.e., package fill level control for certain food categories) Additional sections of 21CFR control and direct GMP (110-111), while others control the packaging of specific food categories and systems (e.g., 113, thermally-processed low acid foods and 129, bottled water) 21CFR may categorize foods, ingredients and materials by type, processing method, packaging methods and other qualifiers. Manufacturers and suppliers are strongly...
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...homepage: www.elsevier.com/locate/scitotenv Effects of meteorology and secondary particle formation on visibility during heavy haze events in Beijing, China Qiang Zhang a, Jiannong Quan a, Xuexi Tie b,c,⁎, Xia Li a, Quan Liu a, Yang Gao a, Delong Zhao a a b c Beijing Weather Modification Office, Beijing, China SKLLQG and Key Laboratory of Aerosol Chemistry and Physics, Institute of Earth Environment, Chinese Academy of Sciences, Xian China National Center for Atmospheric Research, Boulder, CO, USA H I G H L I G H T S • • • • The cases of haze formation in Beijing, China were analyzed. The effects of RH on PM2.5 concentration and visibility were studied. Gas-phase to particle-phase conversion under different visibility was analyzed. With high RH, the conversion SO2 to SO4= accounted for 20%. a r t i c l e i n f o Article history: Received 25 July 2014 Received in revised form 5 September 2014 Accepted 24 September 2014 Available online 7 October 2014 Editor: P. Kassomenos Keywords: Beijing Hazes Visibility PM2.5 PBL Secondary particle formation a b s t r a c t The causes of haze formation in Beijing, China were analyzed based on a comprehensive measurement, including PBL (planetary boundary layer), aerosol composition and concentrations, and several important meteorological parameters such as visibility, RH (relative humidity), and wind speed/direction. The measurement was conducted in an urban location from Nov. 16, 2012 to Jan. 15...
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...characteristics of wood and the application of this knowledge to industrial processes; including the utilization of wood and the design, production, manufacture, or reconstruction of wood products. The responsibilities of the wood technologist are varied, but generally fall into the broad categories of technical control, production, distribution or research. Technical control may include selection and procurement of raw material, equipment, and supplies, quality control of products, technical supervision of processes, and product development. Production involves supervision of processes, departments or plants and thus requires, in addition to technological knowledge, a grasp of administrative and industrial engineering skills. Distribution may be of materials, supplies, and equipment to the wood-using industry or of the products manufactured. Research, in addition to wood conversion activities, wood technologists also fill research roles to develop the knowledge on which technological advances in the wood industry are based. A wood technology education must provide a basis from which specialization in any of the above areas may develop through either work experience or additional formal education. As with engineering, professional courses in wood technology are built on a strong background in mathematics and physical sciences. Although some knowledge of biology is necessary, most types of wood conversion do not require the depth of understanding of biology that is essential to...
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...Special requirements are placed on both the substantial converting industry as well as research and development regarding the efficiency of raw materials and product lines as well as sustainability. “The development of biorefineries represents the key for the access to an integrated production of food, feed, chemicals, materials, goods, and fuels of the future” PRINCIPLES OF BIOREFINERIES Fundamentals Biomass is similar to petroleum as a complex composition. Its primary separation into main groups of substances is appropriate. Subsequent treatment and processing of those substances lead to a whole palette of products. Petrochemistry is based on the principle of generating from hydrocarbons simpleto-handle and well-defined chemically pure elements in refineries. In efficient product lines, a system based on family trees has been built, in which basic chemicals, intermediate products, and sophisticated products are produced. This principle of petroleum refineries must be transferred to biorefineries. Biomass contains the synthesis performance of nature and has another C:H:O:N ratio than petroleum. The biotechnological conversion will become, besides the chemical, a big player in the future BIOREFINERY SYSTEMS Background Currently, four complex biorefinery systems are the focus in research and development: 1. the lignocellulosic...
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...Harvesting solar energy as a source of power Photosynthetic microorganisms, such as micro-algae and cyanobacteria are able to harness low-intensity solar energy and store it as latent chemical energy in the biomass. This energy can then be released via biochemical conversion. The structural and storage carbohydrates in biomass have low energy content and it is necessary to concentrate the energy content further for fuel application. Anaerobic microbial fermentation is an efficient and widely used method for such conversion process. Useful renewable fuels produced by microorganisms include hydrocarbon, ethanol, methane and hydrogen. Biofuel cells which can release energy in fuel chemicals to generate electrical energy at ambient temperature have been developed. Photo-biological hydrogen production: Chloroplast of some photosynthetic microorganisms such as the green alga chlorella in the presence of suitable electron acceptors is capable of producing H2 and O2 through direct photolysis of water. In the system, the substrate (electron donor) is water, sunlight as the energy source is unlimited, and the product (hydrogen) can be stored and is non-polluting. Moreover, the process is renewable, because when the energy is consumed, the substrate (water) is regenerated. Ultimately, the sun is the only large renewable source of energy. • We have a lot, but it is diffuse and not in a form we can use of most things for which we need energy. Useful energy is in electrons! • So, the...
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...1. a natural resource - Meets our biological and economic needs and wants 2. renewable resource - any natural resource (as wood or solar energy) that can be replenished naturally with the passage of time 3. the year 2100 scientists forecast global warming 4. resource depletion - exhaustion of raw materials within a region 5. waste assimilation - is the ability of the environment to absorb, detoxify, and disperse wastes to make them less harmful 6. best first principle - humans use the highest-quality sources of natural resources and environmental services first 7. sustainability - able to be maintained at a certain rate or level. 8. the collapse of the civilization of people on Easter Island, the cause. - forest destruction 9. system - able to be maintained at a certain rate or level. 10. a nonrenewable resource - resource that does not renew itself at a sufficient rate for sustainable economic extraction in meaningful human timeframes 11. 70% of the world's marine fish stocks - are heavily exploited depleted or slowly recovering 12. a lower-quality natural resource * 13. global fish depletion and the Japanese long line fishing industry * 14. The U.S. clean air act - was passed in 1963* 15. Gross Domestic Product - The monetary value of all the finished goods and services produced within a country's borders in a specific time period 16. The human development index - composite statistic...
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... Teresa Bartley NEW TECHNOLOGIES IN ENVIRONMENTAL MANAGEMENT University of Maryland University College Spring 2009 Table of Contents 1.0 Introduction 1.1 Waste to energy definition/history/uses 1.2 Agricultural / Animal waste production 1.3 Graph, chart, quantities produced in United States, etc.. 2.0 Conversion of w2e 2.1 Conversion Pathways 2.1.1 Thermochemical 2.1.2 Biochemical 2.1.3 Physico-chemical 2.2 Factors affecting energy recovery 3.0 Agricultural Residue 3.1 Introduction to residue 3.2 What is it 3.3 Where is it produced 3.4 What is role in environment 3.4.1 Environmental risks 3.4.2 Health risks 3.5 Conversion of agricultural residue to energy 3.5.1 Process 3.5.2 Risks 3.5.3 Benefits 3.5.4 Future as energy source 4.0 Animal Wastes 4.1 Introduction to animal waste 4.2 What is animal waste comprised of 4.3 Where is it produced 4.4 What is its role in environment 4.4.1 Environmental risks 4.4.2 Health risks Table of Contents (Cont’d) 4.5 Conversion of animal waste to energy 4.5.1 Process 4.5.2 Risks 4.5.3 Benefits 4.5.4 Future as Energy source 5.0 Processes/Regulations/Technology 5.1 Availability of w2e facilities, costs 5.2 Technological benefits/risks 5.2.1 Other information on technology of w2e, production, transportation, environmental implications 5.3 Regulation governing w2e 6.0 Recommendations 6.1 Policy recommendations/guidelines 6.2 Future benefits 7.0...
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...WASTE TO ENERGY NEW TECHNOLOGIES IN ENVIRONMENTAL MANAGEMENT University of Maryland University College Spring 2009 Table of Contents 1.0 Introduction 1.1 Waste to energy definition/history/uses 1.2 Agricultural / Animal waste production 1.3 Graph, chart, quantities produced in United States, etc.. 2.0 Conversion of w2e 2.1 Conversion Pathways 2.1.1 Thermochemical 2.1.2 Biochemical 2.1.3 Physico-chemical 2.2 Factors affecting energy recovery 3.0 Agricultural Residue 3.1 Introduction to residue 3.2 What is it 3.3 Where is it produced 3.4 What is role in environment 3.4.1 Environmental risks 3.4.2 Health risks 3.5 Conversion of agricultural residue to energy 3.5.1 Process 3.5.2 Risks 3.5.3 Benefits 3.5.4 Future as energy source 4.0 Animal Wastes 4.1 Introduction to animal waste 4.2 What is animal waste comprised of 4.3 Where is it produced 4.4 What is its role in environment 4.4.1 Environmental risks 4.4.2 Health risks Table of Contents (Cont’d) 4.5 Conversion of animal waste to energy 4.5.1 Process 4.5.2 Risks 4.5.3 Benefits 4.5.4 Future as Energy source 5.0 Processes/Regulations/Technology 5.1 Availability of w2e facilities, costs 5.2 Technological benefits/risks 5.2.1 Other information on technology of w2e, production, transportation, environmental implications 5.3 Regulation governing w2e 6.0 Recommendations 6.1 Policy recommendations/guidelines 6.2 Future benefits 7.0...
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...The application of nanoscale materials and structures, usually ranging from 1 to 100 nanometers (nm), is an emerging area of nanoscience and nanotechnology. Nanomaterials may provide solu- tions to technological and environmental challenges in the areas of solar energy conversion, catalysis, medicine, and water treatment [1,2]. This increasing demand must be accompanied by “green” synthesis methods. In the global efforts to reduce generated hazardous waste, “green” chemistry and chemical processes are progressively integrating with modern developments in science and industry. Implementation of these sustainable processes should adopt the 12 fundamental principles of green chemistry [3–7]. These principles are geared to guide in minimizing the use of unsafe products and maximizing the efficiency of chemical processes. Hence, any synthetic route or chemical process should address these principles by using environmentally benign solvents and nontoxic chemicals [3]. Nanomaterials often show unique and considerably changed physical, chemical and biological properties compared to their macro scaled counterparts [8]. Synthesis of noble metal nanoparticles for applications such as catalysis, electronics, optics, environmental, and biotechnology is an area of constant interest [9–15]. Gold, silver, and copper have been used mostly for the synthesis of stable dispersions of nanoparticles, which are useful in areas such as photography, catalysis, biological labeling...
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...semiconductor based solar cells harnessing solar energy. Photosynthesis is the process of converting solar energy into chemical energy in the form of carbohydrates. For photosynthesis to occur a few factors must be present such as water, carbon dioxide, chlorophyll, and light energy. Photosynthesis consists of two sets of reactions the first being the photo portion or light reaction which is the reaction that captures solar energy the second being the synthesis reaction or Calvin cycle reactions which converts that solar energy into carbohydrates (Mader, 2010). For light reactions to occur first light energy enters the cells and is absorbed by the chlorophyll. That Light energy raises the energy level chlorophyll enabling electrons to be freed form the chlorophyll molecules. This makes the chlorophyll molecules positively charged the electrons from hydrogen atoms are attracted to the positively chlorophyll causing water molecules to break apart into oxygen atoms. The elections freed from the chlorophyll and the protons freed from water take part in the chemical reactions in the cell. The reactions result in the production of adenosine triphosphate (ATP) and nicotinamide adenine di nucleotide hydrogen phosphate (NADPH2) (Chaney, 2012). The products of light reactions ATP and NADPH2 are used in the Calvin cycle reactions. The Calvin cycle consist of three processes carbon dioxide fixation, carbon dioxide reduction and regeneration of the first substrate (Book). Carbon dioxide...
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...Photosynthesis The sun is our most powerful source of energy, the ultimate source of energy for nearly all life on Earth. Sunlight can be used for heating, lighting and cooling homes and other buildings, generating electricity, water heating, and several other processes. Plants and certain other organisms are able to capture solar energy and carry on photosynthesis, a process that transforms solar energy into the chemical energy of nutrient molecules. Animals and plants get energy by metabolizing nutrient molecules made by photosynthesis (Mader, 2012). Most of this solar radiation is in the form of invisible ultraviolet and infrared frequencies, as well as the spectrum of visible light. But the most important use of solar radiation by living organisms is photosynthesis, the direct conversion of visible light into usable energy for plant and animal life, and oxygen to breathe. Only a vanishingly small part of the total amount of radiation given off by the sun actually reaches earth, and only a portion of that is utilized by photosynthesizing organisms (Shields and Teng, 2012). Photosynthesis is the process of producing and releasing oxygen in the air. It needs sunlight, carbon dioxide and water. During the process of photosynthesis, the plants decompose the molecules of hydrogen and carbon-dioxide into hydrogen; carbon and oxygen produce glucose which forms the source of their energy, growth and food. For plants their main source of energy is photosynthesis, which is used...
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...View Online / Journal Homepage / Table of Contents for this issue Catalysis Science & Technology Cite this: Catal. Sci. Technol., 2012, 2, 2025–2036 www.rsc.org/catalysis Dynamic Article Links MINIREVIEW Advances in conversion of hemicellulosic biomass to furfural and upgrading to biofuels Saikat Dutta, Sudipta De, Basudeb Saha* and Md. Imteyaz Alam Downloaded on 15 September 2012 Published on 01 June 2012 on http://pubs.rsc.org | doi:10.1039/C2CY20235B Received 14th April 2012, Accepted 28th May 2012 DOI: 10.1039/c2cy20235b Recent approaches to furfural synthesis from hemicellulosic biomass and pentose sugars with both homogeneous and solid acidic catalysts have been summarized by addressing the associated sustainability issues. The features of deconstruction of hemicellulosic biomass by acid hydrolysis to produce pentose sugar feedstock for furfural have been discussed in brief. Several strategies including solvent extraction in a biphasic process, application of surface functionalized materials such as acidic resins, mesoporous solids and mechanistic insight in limited cases are discussed. The present status of the promising furfural platform in producing second generation biofuels (furanics and hydrocarbon) is reviewed. The performances of each catalytic system are assessed in terms of intrinsic reactivity and selectivity toward furfural production. Overall, this minireview attempts to highlight the scope of further developments for a sustainable furfural...
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...ENVIRONMENTAL/ECOLOGICAL SUSTAINABILITY ........................... 5 ECONOMIC SUSTAINABILITY: ................................................................. 6 SOCIAL SUSTAINABILITY: ....................................................................... 7 OPPORTUNITIES & CONSTRAINTS IN ORGANIC AGRIBUSINESS ........ 7 OPPORTUNITIES ......................................................................................... 7 CONSTRAINTS ............................................................................................. 8 SUSTAINABLE PRINCIPLES OF ORGANIC INTEGRATED AGRIBUSINESS – GOALS/KEY FEATURES OF THE ORGANISATION . 10 DESIGNING THE ORGANIC PRODUCTION SYSTEM .............................. 12 MANAGING THE CONVERSION TO ORGANIC FARMING.................. 13 CHALLENGES IN CONVERSION PROCESS ........................................... 14 VALUE CHAIN ANALYSIS OF A TRADITIONAL AGRICULTURE SYSTEM...
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